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The Next Generation of Nuclear Reactor Designs
Prof. Sama Bilbao y Len
Source: PRIS, IAEA, 01/2012
Reactors Currently in Operation
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3
Reactors Currently in Operation
TYPE Number of Units Total Capacity
[MWe]
BWR 84 77,621
FBR 2 580
GCR 17 8,732
LWGR 15 10,219
PHWR 47 23,160
PWR 270 247,967
TOTAL 435 368,279
Source: PRIS, IAEA, 01/2012
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4
Nuclear Electricity Generation
Source: PRIS, IAEA, 01/2012
5
5
Nuclear Share of Electricity in the US
Source: US Energy Information Administration's Electric Power Monthly (08/16/2011)
6
6
Age of the current fleet
Source: PRIS, IAEA, 01/2012
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7
Availability Factors
Source: PRIS, IAEA, 01/2012
U.S. Nuclear Industry Capacity Factors 1971 2010, Percent
Source: Energy Information Administration
Updated: 4/11
U.S. Electricity Production Costs 1995-2010, In 2010 cents per kilowatt-hour
Production Costs = Operations and Maintenance Costs + Fuel Costs. Production costs do not include indirect costs and are based on FERC
Form 1 filings submitted by regulated utilities. Production costs are modeled for utilities that are not regulated.
Source: Ventyx Velocity Suite
Updated: 5/11
Reactors Currently under Construction
Source: PRIS, IAEA, 01/2012
Reactors Currently under Construction
Under Construction
Type No. of
Units
Total
MW(e)
BWR 4 5,250
FBR 2 1,274
LWGR 1 915
PHWR 4 2,582
PWR 52 51,011
Total: 63 61,032
Source: PRIS, IAEA, 08/2011
Source: US NRC
08/2011
http://www.nrc.gov
New Nuclear in the US
New Nuclear in the US
Source: US NRC, 02/2012
Application for
Construction License
Reactor
Operation
Application for Operation
License
Construction
License to Build
License to
Operate
Two Step Licensing (Part 50)
One Step Licensing (Part 52)
US NRC Design Certification
Toshiba ABWR December 2011
GE-Hitachi ABWR under review
Westinghouse AP-1000 December 2011
GE-Hitachi ESBWR Expected May 2012
Water Cooled Reactors Light Water Cooled (BWR, PWR) Heavy Water (PHWR, CANDU type)
Gas Cooled Reactors CO2
(GCR) Helium (HTGR)
Liquid Metal Cooled Reactors Sodium Lead or Lead-Bismuth
Molten Salt Reactors Fluorides (LiF)
Chlorides (NaCl table salt)
Fluoroborates (NaBF4) + others
Mixtures (LiF-BeF2),
Eutectic compositions (LiF-BeF2 (66-33 % mol))
Types of Nuclear Reactors Coolant
Light Water Moderated
Heavy Water Moderated
Graphite Moderated
Non-moderated
Types of Nuclear Reactors Moderator
Thermal Reactors
Epithermal Reactors
Fast Reactors
Types of Nuclear Reactors Neutronic Spectrum
Solid Fuel Fuel pins Fuel pebbles
Liquid Fuel
Solved in the coolant
Types of Nuclear Reactors Fuel Type
Burners
Breeders
Types of Nuclear Reactors Conversion Rate
Nuclear Fission
Pressurized Water Reactor (PWR)
Boiling Water Reactor (BWR)
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Pressurized Heavy Water Reactor (PHWR)
1. Nuclear Fuel Rod
2. Calandria
3. Control Rods
4. Pressurizer
5. Steam Generator
6. Light Water Condensate pump
7. Heavy Water Pump
8. Nuclear Fuel Loading Machine
9. Heavy Water Moderator
10. Pressure Tubes
11. Steam
12. Water Condensate
13. Containment
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Gas Cooled Reactor
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Advanced Reactor Designs (defined in IAEA-TECDOC-936)
Evolutionary Designs - achieve improvements over existing designs through small to moderate modifications
Innovative Designs - incorporate radical conceptual changes and may require a prototype or demonstration plant before commercialization
Engineering
Some R&D
and Confirmatory
testing
Co
st o
f D
eve
lop
me
nt
Departure from Existing Designs
Prototype or
Demonstration plant
R&D
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Another classification
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Cost Reduction Standardization and series construction
Improving construction methods to shorten schedule
Modularization and factory fabrication
Design features for longer lifetime
Fuel cycle optimization
Economy of scale larger reactors
Affordability SMRs
Performance Improvement Establishment of user design requirements
Development of highly reliable components and systems, including smart components
Improving the technology base for reducing over-design
Further development of PRA methods and databases
Development of passive safety systems
Improved corrosion resistant materials
Development of Digital Instrumentation and Control
Development of computer based techniques
Development of systems with higher thermal efficiency and expanded applications (Non-electrical applications)
Global Trends in Advanced Reactor Design
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Boiling Water Reactors (BWR)
ESBWR
GE
1550 MWe
KERENA
AREVA & E.On
1250+ MWe
ABWR-II
GE, Hitachi, Toshiba 1700 MWe GE, Hitachi,
Toshiba
ABWR
1380 MWe 1500 MWe
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Advanced Boiling Water Reactor (ABWR)
Originally by GE, then Hitachi & Toshiba
Developed in response to URD
First Gen III reactor to operate commercially
Licensed in USA, Japan & Taiwan, China
1380 MWe - 1500 MWe
Shorter construction time
Standardized series
4 in operation (Kashiwazaki-Kariwa -6 & 7, Hamaoka-5 and Shika-2)
7 planned in Japan
2 under construction in Taiwan, China
Proposed for South Texas Project (USA)
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ABWR-II
Early 1990s TEPCO & 5 other utilities, GE, Hitachi and Toshiba began development
1700 MWe Goals
30% capital cost reduction reduced construction time 20% power generation cost
reduction increased safety increased flexibility for future
fuel cycles
Goal to Commercialize latter 2010s
36
ESBWR
Developed by GE Development began in 1993 to improve
economics of SBWR 4500 MWt ( ~ 1550 MWe) In Design Certification review by the U.S.NRC
expected approval 06/2012 Meets safety goals 100 times more stringent
than current 72 hours passive capability Key Developments
NC for normal operation Passive safety systems
Isolation condenser for decay heat removal
Gravity driven cooling with automatic depressurization for emergency core cooling
Passive containment cooling to limit containment pressure in LOCA
New systems verified by tests
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KERENA = SWR-1000
AREVA & E.On
Reviewed by EUR
1250+ MWe
Uses internal re-circulation pumps
Active & passive safety systems
Offered for Finland-5
Gundremingen reference plant
New systems verified by test (e.g. FZ Jlich test of isolation condenser)
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Pressurized Water Reactors (PWR)
ATMEA AREVA+Mitsubishi
1100 MWe
AP-1000
Westinghouse
1100 MWe
WWER-1000/1200
Gidropress
1000 1200 MWe
EPR AREVA
1600+ MWe
APWR
Mitsubishi 1540 1700 MWe
APR-1400
KHNP 1400 MWe
39
Advanced Pressurized Water Reactor (APWR) Mitsubishi Heavy Industries & Japanese utilities
2x1540 MWe APWRs planned by JAPC at Tsuruga-3 & -4 and 1x1590 MWe APWR planned by Kyushu EPC at Sendai-3
Advanced neutron reflector (SS rings) improves fuel utilization and reduces vessel fluence
1700 MWe US APWR in Design Certification by the U.S.NRC
Evolutionary, 4-loop, design relying on a combination of active and passive safety systems (advanced Accumulator)
Full MOX cores
39% thermal efficiency
Selected by TXU for Comanche Peak 3 and 4
1700 MWe EU-APWR to be evaluated by EUR
40
EPR
AREVA 1600+ MWe PWR Incorporates experience from Frances N4 series and Germanys
Konvoi series Meets European Utility Requirements Incorporates well proven active safety systems
4 independent 100% capacity safety injection trains Ex-vessel provision for cooling molten core Design approved by French safety authority (10.2004) Under construction
Olkiluoto-3, Finland (operation by 2012?) Flamanville-3, France (operation by 2012)
Taishan-1 and 2, China (operation by 2014-2015) Planned for India U.S.NRC is reviewing the US EPR Design Certification Application
EPR
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WWER-1000 / 1200 (AEP)
The state-owned AtomEnergoProm (AEP), and its affiliates (including AtomStroyExport (ASE) et.al) is responsible for nuclear industry activities, including NPP construction
Advanced designs based on experience of 23 operating WWER-440s & 27 operat